Fluid distribution and control apparatus



Jilly 1944- D. G. GRlSl VOLD 2,352,629

FLUID DISTRIBUTION AND CONTROL APPARATUS Original Filed May 1'7. 1939 8 Sheets-Sheet l INVENTOR 5M2; 7AM,

ATTORN EYS y 1944- D. G. GRISWOLD 2,352,629

' FLUID DISTRIBUTION ANO CONTROL APPARATUS Original Filed May 17, 1939 8 Sheets-Sheet 2 ATTORNEYS J 1944- D. G. GRISWOLD 2,352,629

FLUID DISTRIBUTION AND CONTROL APPARATUS I Ofiginal Filed May 17, 19:9 8 Sheets- Sheet s IINVENTOR flail QM' ATTORNEYS y 4, 1944. D. G. GRISWOLD 2,352,629

FLUID DISTRIBUTION AND CONTROL APPARATUS Original Filed May 17, 1939 a Sheets- Sheet 4 INVENTOR flalzagd 6 rziswald ATTORNEYS y 1944- D. s. GRlSWOLD 2,352,629

FLUID DISTRIBUTION AND CONTROL APPARATUS Original Filed My 17, 1939 8 Sheets-Sheet 5 I INVENTOR Jar 20in; 6 Grz'azavid ATTORNEY$ 1944. D. G. GRISWOLD 2,352,629

I FLUID DISTRIBUTION AND CONTROII'APBARATUS Original Filed May 17, 1939- 8 Sheets-Sheet 6 IN ENTOR zw d z 63 awmzd ATTORNEYS July 4, 1944. D. G. GRISWOLD FLUID DISTRIBUTION AND CONTROL APPARATUS Original Filed May 17, 1939 8 Sheets-Sheet 7 mVENToR fionald 6. 'rz'swold 3 7 ATTORNEYS y 944. D. G. GRISWOLD 2,352,629

FLUID DISTRIBUTION AND CONTROL APPARATUS I Original Filed May 17. 1939 8 Sheets-Sheet 8 41/ J50 INVENT'OR 50:; P fianagg 6. rzswald AT RN Patented Jil i rwm msramn'rrou AND coN'raoL mma'rus Donald G. Griswold, Alhambra, Calif., asslgnor to Clayton Manufacturing Company,

Calif.

Alhambra.

Original application May 17, 1939, Serial No.

274,288, now Patent No. 2,243,815, dated May Divided and this application March 11, 1941, Serial N0. 382,802

16 Claims. (01. 137-144) The present invention relates to fluid distribution and control apparatus and especially to fluid distribution and control apparatus for water softening systems adapted to effect regeneration of the system at the will and convenience of the user.

"The invention further relates to fluid distribu-,

tion means for a water softening system having treating a bed of material to effect periodic regeneration thereof. v

In general, the invention relates to a fluid distribution system and control means for use with water softening systems of the type employing a bed of zeolite having the property of exchanging its normal sodium base for calcium and mag: nesium; the principal substances dissolved in water that impart hardness thereto.

The fluid distribution unit of the present in vention is of extremely compact construction and comprises six diaphragm valves arranged to be operated in pairs and all controlled simultaneously by a master pilot valve to effect normal softening service and the successive steps of the regenerating cycle, to wit, backwashing, salting and rinsing. The fluid distribution unit further comprises a built-in injector actuable by the flow of water under the control of one of said diaphragm valves fordrawing brine from a brine tank during the salting step.

-When the present system is in normal service, that is, when the water softener is functioning to soften water, the control knob and master pilot valve disc are in what may be termed their normal inoperative position, but the master pilot valve disc at this time is in such position and cooperates with the fluid distribution device or unit in such manner that the fluid pressure on one pair of diaphragm valves only is relieved through the pilot valve, permitting this pair of Valves to open and allow an uninterrupted flow of raw and softened water through the distribution device.

water flows from the distribution device into the upper end of the softener, and softened water flows from the lower end of the softener back to the distribution device and, finally, from thu.

- distribution device into the service line to the as the pressure is relieved on the pair of valves mentioned, the remaining four valves are subjected to fluid pressure and are maintained in closed position thereby.

' After the system has been in operation for a period of, say, one to. two weeks, and the indications are that it requires regeneration, the user need only turn the control knob through approximately half a revolution in a clockwise direction to initiate the cycle of regeneration. The rotation of, the control knob rotates the master pilot valve disc and also winds the spring in the timing mechanism. The wound spring in turn storesthe energy for rotating the drive shaft connected with the niaster pilot valve disc to impart rotation to said valve and return it slowly to its initial position. The rotation of the master pilot valve disc through-a half revolution from its normal position results in the application of fluid pressure to close the above mentioned pair of diaphragm valves, which pro vide for normal softening operation, and to relieve the pressure on a second pair of diaphragm valves to permit the same to open. This'second pair of valves is arranged in the distribution unitso as to cause the water to flow in a reverse direction therethrough to the water softener and provide a backwashing operation for flushing sediment, vetc., out of the softener tank. -During backwashing, the flow of water is from the distribution unit to the lower end of the softener tank, out of theupper end of the softener tank and back to the distribution unit, andifinally,

from the distribution unit into a drain. The

above reverse circulation or backwashing operation continues for a period of time predetermined by the timing mechanism and the porting arrangement of the master pilot valve disc and may last anywhere from about five to ten minutes or more, as required by such factors as the pressure of the water, size of the softening bed, the amount of foreign matter or dirt left in the bed by the water which has been treated, etc. It will be understood that, while the second pair of diaphragm valves is open, the remaining four diaphragm valves are maintainedin closed posi- Suitable piping connects the dis- 4 tion by the application of fluid pressure thereto.

Upon completion of the backwashing step, the drive shaft of the timing mechanism will have rotated the master pilot valve disc to a position such as to relieve the ressure on, and thereby permit theopening of, still a third pair of diaphragm valves, while at the same time admitting fluid pressure to the first and second pairs point of use. It is to be understood that so long I56 ,of valves to maintain them in closed position.

This third pair of valves is so arranged in the fluid'distribution unit as to operate the injector housed in the fluid distribution unit and thereby control the salting step, i. e., the injection of the regenerating solution into the upper end of the softening tank. During the salting step, the

follows: water flowing into the distribution unit is diverted into the injector, the injector is thus operated to draw brine from the brine tank, and the brine entering the distribution unit is carried along with the water to the upper end of the softening tank. The brine flows through the zeolite' bed in the softening tank; discharges at the lower end of the tank, is returned to the distribution unit and is discharged from the distribution unit through the same drain beforementioned. After the charge of brine has been exhausted from the brine tank, raw water continues to flow through the system in the path depressure fluid is applied to the second and thirdmentioned 'pairs of valves to maintain them closed so that the system then assumes its nor-. ,mal function of softening water. The path of flow of water then is through the distribution valve to the upper end of the softener tank, through the softening bed, from the lower poraon'or the tank to the distribution device and then into the service line to the point of use, as aforedescribed.

One of the important features of the present invention is to provide a fluid distributing device which may be associated with a brine tank control mechanism in a manner to provide for salting. operations. The brine tank control mechanism is fully described in my Patent 2,243,815 (Serial No. 274,288, filed May 17, 1939), issued on May 2'7, 1941, for Water softening apparatus," of which this case is a division, and hence said mechanism need not be described in great detail herein.

One of the principal objects of the invention is to provide a fluid distribution device and control for water softening apparatus arranged so that said apparatus can be regenerated at the will and convenience of the user.

Another object of the invention is to provide fluid distribution and control means for a water flow of liquid through the distribution unit is as pair of valves, permitting these to open, and

softening apparatus which requires a minimum of attention on the part of the user.

Another object of the inventionis to provide fluid distribution and control means for a water softening apparatus which does not require the presence of the user at the side thereof during the cycle of regeneration.

Another object of the invention is to provide fluid distribution and control means for a water softening system which is semi-automatic in operation, that is, requires manual operation to initiate the regenerating cycle, but is otherwise fully automatic.

vide a fluid distribution system and control.

means for water softening apparatus which eliminates the inconveniences and the expense of maintenance encountered with more complex manual and fully automatic water softening systems.

Another object of the invention is to provide, in water softening apparatus, novel control .means for automatically timing the various steps 10 in the cycle of regeneration.

Another object of the invention is to provide a fluid distribution device or unit which operates quietly without line shock, chatter or vibration.

Another object of the invention is to provide a fluid distribution device or unit and control means therefor which requires only a very small force to operate, irrespective of the pressure of the fluid flowing through said fluid distribution device or unit.

Still another object of the invention is to provide a fluid distribution device or unit of compact yet relatively simple construction for controlling the flow of water and brine to the softer tank.

A still further object of the invention is to provide control means for starting and controlling the cycle of regeneration of a water softening system from a point remote from the apparatus.

other and further objects of the invention will be apparent from the following description taken in conjunction with the accompanying drawings, in which:

Figure 1 is a diagrammatic elevational view of a water softening apparatus embodying one form of fluid distribution and control means based upon the principles of the present invention, the brine tank being shown in cross section;

Figure 2 is a sectional view taken on the line -22 of Figure 1;

Figure 3 is a sectional view through the master control device and the fluid distribution device or unit, taken 'on the line 33 of Figure 1;

Figure 4 is a sectional view taken on the line 4-4 of Figure 3, showing an exterior view of the cover plate and various details of the fluid distribution device orunit;

Figure 5 is a sectional view taken on the line 5-5 of Figure 3 showing the details of the grooving and porting in the underside of the cover plate of the fluid distribution device or unit;

Figure 6 is "a sectional view taken on the line 6-45 of Figure 3 showing the body portion of the fluid distribution device in elevation;

Figure 7 is a sectional view through the fluid distribution device taken on the line 1-1 of Figure 4, showing the diaphragm valves l and 2, which control the flow of raw water to the softener during the normal softening operation, in open position;

Figure 8 is a similar sectional view taken on the line 8-8 of Figure 4, showing the diaphragm valves 5 and 6, which control the backwashing operation, in closed position;

Figure 9 is a further similar sectional view taken on the'line 9-9 of Figure 4, showing the diaphragm valves 3 and l, which control the salting and rinsing operations, in closed position;

Figure 10 is a transverse sectional view through the fluid distributiondevice, taken on the line Ill-Ill of Figure 9;

Figure 11 is a view of the combined gasket and diaphragm employed in the present fluid distribution device and showing certain parts of the valves 1, 2, 3, l, 5 and 6 assembled therewith:

'Still another object of the invention is to pr'g- 7| Figure 12 is a detail elevational view of the therefrom is upward toward the inside of the tank head-l5. Y

The tank l4 of the softener A contains a bed I4 of zeolite (or other water softening material). Discharge piping I1 is arranged adjacent the bottom of the tank l4 and conducts the water that'has passed through the bed It back to the distribution device C. A portion of the pipe l1 lies within the tank l4 and is provided with a Figure is a perspective view of the opposite side of the master pilot valve disc and the means for rotating the same; 4

Figure 16 is a perspective view of the valve seat which cooperates with the master pilot valve disc, the gasket which is interposed between the end of the housing of the master control unit and the fluid distribution device, and the distribution plug of the fluid distribution device;

Figure. 1'7 is a view of the outer face of the fluid distribution plug;

Figure 18 is an inverted plan view of the distribution plug as viewed in Figure 17;

Figure 19 is a diagrammatic view illustrating the flow through the fluid distribution device during normal softening service;

Figure 20 is a similar view showing the flow during the backwash period;

Figure 21 is another similar view showing the flow during the salting and rinsing period;

Figure 22 is a. schematic view illustrating the relative position of the control knob and the ports and grooves in the master pilot valve disc illustrating the manner in which pressure and exhaust fluid may be conducted from the master series of downwardly facing slots "a. The soft ened water enters the distribution device through the piping l'l connected with an opening conveniently referred to as'a return opening and passes therethrough in a manner which will-also' be. explained hereinafter and ultimately discharges through a service opening into a service pipe l8. One end of a drain pipe [9 isconnected to a waste opening in said distribution device for a purpose set forth later herein.

The brine tank B contains a bed of salt 20'and the usual layer of coarse gravel 20a. A pipe 2| control unit or device to the fluid distribution device; and

Figure 27 is a diagrammatic view partly in section showing the details of connecting various ports in the master control device with correspondipg ports in the fluid distribution device.

Referring now to the form of the invention shown in Figures 1 to 24, inclusive, and more particularly to Figure 1, the water softener is generally designated by the letter A, the brine tank by B, the fluid distribution device or unit by C, the manually operable master control device for starting the regenerating cycle by D,

and the float-controlled valve and its associated linkage on the brine tank by E.

Raw water, i. e., the water to be treated, is introduced into the system through a supply pipe ll connected to an inlet opening at one side of the fluid distribution device C. The raw water introduced by the supply pipe II flows through various passageways in the fluid distribution device C, as will be explained later, and is then conducted from an outlet opening of said distribution device to the softener A by piping generally indicated at l3. As is clearly shown in Figure 2, the piping I3 extends into asoftener tank l4 and therefore need not be described in detail.

is preferably arranged so that the discharge extends through the salt bed 20, as shown in I Figure 1, and one end 22 thereof is perforated and projects into the layer of gravel 20a. The opposite end 23 of the piping 2| is connected to a float controlled diaphragm valve-generally indicatedby the numeral 24. A pipe 25 connects the diaphragm valve 24 with the distribution device C. V

The master control device D is best illustrated in Figure 3, and comprises a main housing 40 and a hinged cap 4| pivotally mounted at one side thereof upon the housing between ears 40a by a pin 42. The-opposite side of the cap H is provided with a projecting tongue 43 which extends between a pair of lugs 44 depending from the housing 40. The tonnage 43 is provided with an aperture 45 located so that it extends inwardly beyond the lugs 44 when the cap is in closed position. The aperture 45 is thus adapted to receive a pin, lock or other means for maintaining the cap in closed position.

A clock mechanism generally designated 46 is mounted within the main housing 40 and is disposed between a'shoulder 41 and a cover plate 48. A gasket 49 is interposed between the 'cover plate 48 and a flange 50 of the main housing. A series of screws 5| retain the cover plate 48, gasket 49 and clock mechanism 46 in assembled relation with the housing 40.

A stop pin 52 is mounted in the cover plate 48 and projects through the top plate of the clock mechanism 48, whereby rotation of the clock' mechanism ,46 relative to the cover plate 48 is prevented.

A control knob 54' is operatively associated with a drive, shaft 55 of the clock mechanism and one end 56-01 said control knob is adapted to engage the stop pin 52 in the normal inoperative position-thereof (see Figures 3 and 12).

The clock mechanism 48 is conventional, and It will be understood from prior statements made herein that the spring of the clock mechanism is wound by manually turning the control knob 54 clockwise for about half a revolution or until the end 56 of said control knob engages a secondstop member 51. Upon release of the control knob 54 the spring will cause the controlknob 54 to slowly return to its initial position; the time required being about thirty minutes. For

- convenience, the face of the cover plate 48 may be inscribed with suitable indicia to indicate the various functions controlled by the master valve. For example, the cover plate shown herein bears the legend "Service" adjacent the stop pin 52 (see Figure 12) to indicate the normal inopera-.

tive position of the control knob 54. The cover plate 48 further bears the legend "Backwash" adjacent the second stop pin 51, which operatioif occurs when the knob 54 is turned clockwise so that its end 58 is brought into engagement bythe drive shaft 55 of the clock mechanism 48 and it in turn drive's a shaft 6| through a'driven element iz suitably secured to one end of the shaft 8|. The driven element 82 is provided with apertures 83 adapted to receive pins 84 carried by the driving member 88. The opposite end of the shaft 8| is rounded as shown at 8 I and is provided with a driving element 85. A master pilot valve disc 88 is arranged in substantially axial alignment with the shaft 8| and is provided, as best shown in Figure 15, with a pair of apertures 81 adapted to receive short pins 81 carried by the driving element 85 and a through aperture 88 adapted to receive a long pin 88*. This arrangement has the advantage that it permits the assembly of the parts in only one way. The apertures 81 and 88 are of greater diameter than the pins IiI and 88 to permit slight relative movement of the disc on the pins. It will, therefore, be apparent from the foregoing that as the drive shaft 55 of the clock mechanism drives the driving element 88, rotation is iniparted to the pilot valve disc 88 through the driven element 82, shaft 8|, and driving element 85.

'The shaft 8| (see Figure 3) is packed in the housing 48 by suitable packings 88 and 18. The packing 88 surrounds the shaft 8| and is engaged by a packing washer II which in turn is engaged by a gland I2 threaded into the housing 48 adjacent the driven element 82. Adjustment of the gland I2 against the washer II compresses the packing 88 to the extent desired to form a suitable seal around the shaft 8|. The packing l8 likewise surrounds the shaft 8| and is compressed between packing washers I3 and 14 by a gland member I5 threaded into the housing 48.

A compression spring 18 surrounds the shaft 8| and one end thereof engages the gland I5. The opposite end of said spring engages a seating washer 'I'I carried by the shaft 8|. The washer I1 is arranged to abut the driving element 85, and, inasmuch as the spring I8 is a compression spring, it tends to urge the driving member 85 toward the pilot valve 88. The spring I8 urges the rounded end 8| of the shaft against the valve disc 88 to hold the same against its seat at all times, as will appear more fully hereinafter.

The master pilot valve disc 88 has opposite fiat faces 88 and 8| (see Figures 13,14 and 15). A plurality of supply ports 82, 83, 84 and 85 extend transversely through the body of the pilot valve and are connected on the side 8| by a pressure fluid supply groove generally indicated bythe numeral 88. In some instances it may be desir-. able to omit ports." and 8 4, inasmuch as. the 'ports 82 and 85 will supply the necessary pressure fluid to the groove 88.

The master pilot valve disc 88 is also provided with a U-shaped exhaust passageway 81 (see Figure 14). One leg as of the U -port a1 is arranged axially of the pilot valve disc and opens into the side 8| thereof. The other leg 88 of said U-shaped exhaust passageway is spaced radially from the axialpassageway 88- and also opens onto the side 8| of said pilot valve disc.

An arcuate drain groove 88 merges with the opening defined by the leg 88 and extends circumferentially in the side 8|. It will be noted that the supply groove 88 and the drain groove 88 I are formed concentric with the axial opening and that the supply ports 82, 88, 84, 85, the exhaust port 8 and the terminal of the drain groove 88 arespaced approximately 60 apart. This spacing, however, is not critical and'may be varied as desired, within limits of course.

The side 8| of the pilot valve 88 is adapted to seat against a flat surface 85 of a valveseat 88 (see Figure 3,). .The valve seat 88 is received in a recess 81 formed in one end of the housing 48. The valve seat 85 is secured to the housing 48 by a pair of screws 88 adapted to extend through openings 88 (see Figure 16) The valve seat 85 is provided with an axial port 88 adapted to register with the axial opening 88 in the pilot valve disc 88. The valve seat 85 is also provided with a series of transverse openings I88, |8| and I82, respectively, which are spaced the'same dis tance from the axis of the valve seat 85 as the supply and drain grooves 88 and 88 of the pilot valve. A pair of dowel pins 88' are provided to assure accurate assembly of the seat with the housing.

A gasket'l85 (see Figures 3, 7 and 16) is interposed between the end of the housing 48 and a boss I88 formed on the cover plate P of the fluid distribution device C. A plurality of screws K 48 clamp said gasket between'the housing 48 and fluid through both of these elements simultaneously. I

The fluid distribution unit or device C comprises a body F, a cover plate P and a combined gasket and diaphragm G interposed between said body and cover plate. The diaphragm is clamped between the body F and cover plate P in fluid tight relation by a series of bolts H which extend through the cover plate and gasket into the body of the distribution valve, as best illustrated in Figure 3. s

The housing F of the distribution device C contaihs six diaphragm valves I, 2, 3, 4, 5 and 8,,

respectively. These valves .are indicated by dotted lines in Figure 4 and by dot-and-dash lines in Figures 6 and 10, respectively. All six valves are of identical construction, and it will suffice for the purposeof the present disclosure to describe only one in detail. For this purpose it will be convenient to refer to Figure "7 which shows the valves in cross section. Each of thevalves I, 2,8, 4,5 and 8 -cons ts of a guide member I having; -a pluralitaDI-Qllegs I|2 circumferentially. spaced from each other. An annular packing washer I|8 engages one side of the guide member I I and is received in a cup ,I I4. The upper external surface of the cup. H4 is preferably made convex, as indicated at H5. The cup II4, washer H3 and the guide III are maintained in. assembled relation by a bolt II6 having an enlarged head II6a. The bolt II6 has a threaded shank II1 received in a threaded opening I I8 in the guide member III. A diaphragm member G is clamped between the convex side II of the cup H4 and the underside of the head II6a. In this manner, the valve is maintained in assembled relation with the diaphragm. The diaphragm G and washer II3 may be compressed to the extent desired by threading the guide I II onto' the shank II1 of the bolt II6. A prick punch may be used to peen a portion of the thread-of the shank onto the underside of the guide to prevent inadvertent disassembly.

Fluid under pressure for operating the valves I, 2, 3, 4, 5 and 6 is supplied by the master pilot valve 66 to a fluid distribution plug X (see Figure mentary shoulder I24 formed in the recess I20.-

The plug X may be inserted into the cover plate P in any desired manner so long as a fluidtight fit is formed between the outer periphery .of said plug and the walls of the recess I20.

The plug X is provided with an axial opening I25 which communicates with a radial exhaust passage I26 extending through the annular portion' I2I of the plug X. The axial opening I25 and the radial passage I26 serve as conduits permitting exhausting of pressure fluid from the dis tribution device C in a manner which will be explained hereinafter.

The fluid distribution plug X is also provided with a transverse passageway I21 which communicates with a longitudinal port I28 and longitudinal passageways I29 and I30. The port I28, the transverse passageway I21 and the longitudinal passageways I29 and I30 serve to supply and exhaust pressure fluid from a pair of diaphragm valves I and 2 providing normal softening operation in a manner which will be fully set out hereinaftei.

The plug X is further provided with a second longitudinal port I3I, a transverse passageway I32 and longitudinal passageways I33 and I34. These ports and passageways serve to supply and exhaust pressure fluid from another pair of diaphragm valves 3 and 4 providing the salting and rinsing in a manner which will be made apparent hereinafter.

The plug X is still further provided with a third longitudinal port I35, a transverse passageway I36 and longitudinal ports I31 and I33. These passageways and ports serve to supply and exhaust pressure fluid from still another pair of diaphragm valves 5 and 6 providing backwash in a manner which will also be made apparent hereinafter. I i

It will be noted from Figure l6-that the ports ports I00, I02, and IOI, respectively, of the valve seat 95. It will "also be understood that the outer respective ends of the transverse passageways I21, I32 and I36 are closed b'y-the walls of the recess I20. I

The plug X is proportioned so that its inner face I39 is substantially flush with the inner face of the cover plate P and its outer face I40 is substantially flush with the surface of the boss I06,

as is also clearly shown in Figure 3.

The axial port I25 extends inwardly from the face I40 and communicates with the exhaust passage I26 in order that spent pressure fluid may be conducted from the axial center of the plug outwardly to its periphery. In order to fa,- cilitate the discharge of fluid from the passageway I26, the boss I06 is provided with an aligned passageway I4I (seeFigure 3). The passageway MI in turn communicates with a transverse pas-v sageway I42 in the cover plate P. The gasket I05 is provided with an opening I43 aligned with the transverse passageway I42 and the combined gasket and diaphragm G is provided with a similar opening I44. The housing 40 is provided with a passageway I45 aligned with the passageway I42 and is further provided with a radial passageway I46 intersecting with the passageway I45 at the point I41. A screw I48 is threaded into the outer end of the passageway I46 to plug the same.

The body F of distribution device C is provided with a threaded opening. I49 (see Figure 3) communicating with the passageways I42, I43, I44 and I45, and a drain pipe I50 is threaded into the opening I49, whereby any fluid which has leaked past the packing 10 will be free to drain from the control unit C.

Referring to Figure5, the inner face I39 of the plug X is provided with a series of relatively shallow grooves communicating with a series of cooperating grooves formed in the inner face of the cover plate P of the fluid distribution device whereby fluid may be introduced into or exhausted from the pressure chambers of the diaphragm valves I to 6 inclusive. More specifically, the plug X is provided with a shallow groove I29 extending from the longitudinal passageway I29 outwardly to the periphery of the plug. The inner face of the cover plate P is provided with an ir regular shaped groove I which is in communication at one end thereof with the shallow groove I29. A passageway I connects the opposite ends of the groove I with a pressure chamber I above the diaphragm valve I.

The inner face I39 of the fluid distribution plug X is also provided .with a second shallow groove I30 which extends from the longitudinal passageway I30 outwardly to the periphery of the plug X. One end of the groove 2* formed in the inner face of the cover plate P communicates with the shallow groove I30, and a passageway I28, I3I, and I35 in the plug X are aligned with end of the radial exhaust passageway I26 and the 2 connects the opposite end of said groove with a pressure chamber 2 positioned above the diaphragm valve 2. 1

The. plug X is further provided with a shallow groove I33 which extends from the longitudinal passageway I33 outwardly to the periphery of the plug X. A groove'3 formed in the inner face of the cover plate P is connected at one end with the shallow groov I33 and its opp site end is connected by a passageway 3 with a pressure chamber 3 located above the diaphragm valve 3. The plug X is still further provided on its inner face with a shallow groove I34 extending from the longitudinal passageway I34 outwardly to the pee riphery of said plug. The innerface of the cover plate P is provided with still another groove 4 connected at one end with the shallow groove I 34' and connected at its other end by a passageway phragm valve 6.

The inner face I39 of the plug X has another shallow groove I31 extending outwardly from .the, longitudinal passageway I31 to the periphery 4 of the plug X. .A groove, 5'- formed in the inner face of the cover plate 1? is connected at one end with said shallowgroove I31 and its opposite end is connected by a passageway 6 with a pressure chamber 5 above the diaphragm valve 5.

The inner face I39 of the plug X is provided with still another shallow groove I38 extending outwardly from the longitudinal passageway I38. A groove 6 formed in the inner face of the cover plate P is connected at one end with said shallow groove I38 and'its opposite end is connected by a passageway 6 with a pressure chamber 6 above the diaphragm valve 6.

The various passageways, valve seats, etc. in the bodyF of the fluid distribution device C are about to be described and it will therefore be convenient to refer to Figures 5 to 10.

As has been stated hereinbefore, raw water is introduced into the distribution device C through the supply pipe II. This water flows from the pipe II into a passageway I69 defined by walls I6I arranged below the seats 5 3' and I' for the valves 5, 3 and I, respectively. This passageway terminates beneath valve seat I at the partition indicated by I62 (Figure 10).

The raw water normally discharges from the distribution device through the pipe I3. This pipe communicates with a passageway I63 shown adjacent to the passageway I69. However, the passageway I63 is separated from the passageway I69 by the wall I6I and the partition I62. The passageway I63 is defined by walls I64 and terminates at the partition I65 below the seat 6' of the diaphragm valve 6 (see Figure 10).

The return of water to the distribution device C from the water-softener normally takes place through the pipe I1 already referred to. Water entering the distribution device from the pipe I1 discharges into a passageway I66 defined by walls and valve's'l, 4, 6 and 6 are closed is diagrammatically shown in Figure 19. The criss-cross hatching here indicates the valves that are closed during normal softening operation. During the backwashing step, valves 5 and 6 are open and valves I, 2, 3 and 6 are all closed, as is diagrammatically shown in Figure 29. The fiow of raw water to the softener is reversed at this timein order that the water will fiow upwardly through the bed in the softener tank and flush it out. Accordingly, raw water introduced through the pipe II enters the passageway I69, but since valves I and 3 are closed and valve 5 is open, the water must leave through the seat 5 of the valve 5. In order to provide egress for the water to pipe I1, an opening I19 somewhat similar to the opening I15 is provided immediately above the partition I69, or in other words, above the seat 5* of the valve 5. Water then flows through the opening I19 into the passageway I66, beneath valve 2 and into pipe I1 Water is discharged from the pipe I1 through the slots I1 at the lower'portion of the softener tank I4. The 'water then flows upwardly through the, softener bed I6 and out of the tank through the pipe I3. the pipe I3 discharges into the passageway I63 which, as has been previously described, extends to a point beneath the valve 6. The valve 6, as has also been stated, is open during the backwash period, therefore water from the passageway I63 passes through the seat 6 of the valve 6. An opening I89 similar to the opening I19 is provided above the seat 6 and abovethe partition I65 to permit flow into a chamber I9I. The chamber I8I lies between the partitions I65 and I69. Water entering this chamber is required to leave the distribution device through the drain pipe I9.

In order to introduce brine into the system to regenerate the softening bed I6, the distribution 0 device C is provided with an injector generally I61 and extending beneath the seats 2' and 4' of 5 end in a partition I69 adjacent the valve seat 5 of the diaphragm valve 6. Thus, the passageways I69 and I66 are separated, by the partition I69 formed by adJacent portions of walls I6I and I61.

Referring to Figures 6, '1 and 19, and especially to Figure '1, the distribution device C is provided with an opening I15 between the seat I' of the valve I and an inwardly extending flange I16 on the body F disposed adjacent to the gasket G. Hence, when valve I is open and valves 5, 3, and 6 are closed, raw water will flow through the pas sageway I69, through the seat I' and opening I15 into the passageway I63, and thence into the pipe I3 leading to the softener tank I4. An openingsimilar to the opening I15 is provided above the seat 2 of valve 2. This opening is indicated at I11 and communicates with a chamber I18 (see Figure 10) adjacent the opening for the service pipe I9. The valve 2 is open at the same time as valve I (as shown in Figure '1) and the softened water enteringthe distribution valve through the pipe l1 then ,fiows into the passageway I66, through the valve seat 2', opening I11 into chamber I19, and thence through service pipe I8 to the point of use. The flowof water through the distribution device when valves I and 2 are open designated by the numeral I85 (see Figure 10) mounted in a housing I86 formed intergral with the body F. The injector comprises a nozzle I91 threadedly mounted in an opening I89 in the housing I86. The nozzle I91 is provided with a tapered orifice I99 arranged so that its smaller valve 3 is open and valves I and 5 are closed, raw

water from the passage I69 will flow through the 5 seat 3' of the valve 3, through the opening I92,

and into the chamber I9I.

A screen I93 (Figure 10) is arranged in the chamber I9I substantially concentric with the nozzle I81. One end of the screen is suitably se-- cured to a boss I96 formed on the nozzle I81 and the opposite end of the screen is received .in a recess I95 formed in a plug I96. The plug I96 is threaded into an opening I91 formed in the housing I86. A gasket I99 is disposed between the housing I96 and the plug I96 to form a seal.

The injector I95 further includes a second nozaasaeaa threaded into the opening I by means of a suit-.

able wrench, and that the nozzle I81 is similarly the nozzles I81 and 200, is provided with an inlet opening 26 into which the brine pipe is threaded.

During the period of regeneration when brine is being circulated through the softener tank I4, the valves 3 and 4 are open and the valves I, 2, 5

and 6 are all closed, as is diagrammatically shown 'in Figure 21. Raw water supplied by the pipe II then enters the passageway I60 and flows through the seat 3 of open valve 3, through opening I02, into chamber .I9I, through tapered orifice 20 I89, into chamber I and then through the plain orifice 203. The effect of this flow is to create a partial vacuum in the chamber I90 and pipe 25. The vacuum thus induced creates a suction permitting opening of the brine control valve 24 in a manner which is fully described in my patent, supra. Upon opening of the valve 24, the injector draws the brinecharge from the brine tank B and both brine and raw water are discharged from the nozzle 200 into the passageway I63. The mixture is then conducted by the pipe I3 into the top of the softener tank I4'so that reaction with and regeneration of the bed I6 occurs by the down-flow of the brine therethrough. The used brine is discharged from the softener tank I4 into the pipe I1 which returns it to the distribution device for flow into the chamber I66. .An open- The strainer plug 2I8 comprises a hollow stem '2I6 having a series of spaced apart annular flanges. 220, 22 I and 222 with openings 223 between the flanges communicating with a central opening 224 in the stem. A screen 225 surrounds the flanges 220, 22I and 222'and serves to screen th openings 223. Thus, pressure fluid must pass through the screen 226 before it can leave the chamber 2H and enter the hollow stem 2". It

- will be noted at this point that the lower portion ing 2! above the partition I68 similar to the opening I80 is provided in the body F, whereby the brine can flow from the passage I66, through the seat 4 of the valve 4, into the passage I8I and finally into the drain pipe I9. It will be understood that the valve 2 is closed during the brining operation and that, therefore, no brine can flow from the passage I66 into the chamber I16 and the service pipe I8.

Flow in the above manner is maintained until i the complete charge of brine has been withdrawn of the distribution device C. Inasmuch as the passageway I60 is always underline pressure, a corresponding pressure will obviously exist in the passageway 2 I2,

' Referring to Figure 3, it will be seen that the of thestem beyond the flange 222 is of greater axial length than the threaded portion 2I9 of the plug and extends into an opening 226 in the housing 40. Thus, the opening 226 will be ob-- structed by the extremity of the stem 2I6 until after the threaded portion 2I9-has been completely backed out of its opening; the object of this arrangement is to permit any water contained in, or flowing into, the chamber 2" to flush foreign matter out of said chamber during the removal of the plug rather than carry it into theo ning 226.

The opening 226 in the housing 40 communicates with the pressure chamber 66 in which the pilot valve 66 is received. This chamber is constantly filled with fluid under pressure for actuating the various diaphragm valves I to 6, inclusive, of the, distribution device C. I

The valve 24 includes a pilot actuating shaft 302, which carries a pilot disc (not shown herein, but fully disclosed in my patent, supra) for controlling the operation thereof. The linkage E associated with the valve 24 comprises an arm 32I fixedly connected at one end thereof, to the pilot shaft 302 and pivotally connected at its opposite 3 end to a hollow rod 350. A bracket 325 is secured to the valve 24 and provides a fulcrum for a lever 342, one arm of which is pivotally connected with the rod 350 and the other arm of which is threaded and carries an adjustable counterweight 3411 A- float 354 is slidably mounted upon the rod 350 btweenstops or collars 353 and 353 which determine the maximum high and low levels, respectively, of the brine in brine tank B.

The counterweight 341 and the associated arm of the lever 342 are of a combined mass sufficient to counterbalance the dead weight of the valve operating linkage comprising the actuating arm 32 I, the other arm of the lever 342 and the hollow rod 350. The counterweight 341 is adjustable lengthwise of the arm 343, whereby the linkage maybe nicely counterbalanced. The weight of level, the weight of the float carries the rod 350 gasket G is provided with an opening 2 I3 in registration with one end of the passageway 2 I2, and further, that the boss I06 .of the cover plate? is provided with a horizontal passageway 2I4. The

gasket I05 is provided with a passageway 2I5 and- 2" formed in said housing. A strainer plug 2I0 bodily downward and thereby moves the arm 32I to an angular position in which its center line is on a radii approximately 60 below the position of said arm shown in Fig. 1. When the liquid level Is rising in the brine tank, instead of falling,

the float 354 will rise on the rod 350 without affecting the position of the arm 32I and lever 342 until it engages the collar 353, whereupon it will carry the rod 350 bodily upward and thereby move the arm 32I and lever 342 to the angular is threaded into the chamber 2I1 as indicated at 15 position shown in Fig. 1,

'2I6. A gasket 2I8 is positioned below the head of the plug toform a water-tight seal.

Let it be assumed that the cycle of regeneration has reached the salting stage and that the arm 82I will then be in its,upper angular position as indicated in Figure 1. Any suction induced inthe pipe 25 at this time by-the injector I85'will tend to create a vacuum in the valve 24. This condition, as explained in my patent, supra, enables the higher or approximately atmospheric pressure on the fluid in the tank B and the pipej 2I to efl'ect opening of the valve 24 to permit the injector I85 to withdraw brine from the brine tank B ,through the pipe '2I, valve 24 and pipe 25 into the chamber I58 oi the fluid distribution device C. The flow of brine from the chamber I88 through the distribution device to the softener tank I4 already has been described in connection with Figure 21, and repetition here would be superfluous.

80 long as the injector I85 continues to draw brine from the brine tank, the brine level will be'lowered and the float- 354 'will descend with said level until it engages the collar 352, and then arm 82 I and lever 342' will be angularly rotated counterclockwise to actuate the pilot shaft 882, as explained in my patent, supra, to close the valve and cut of! the supply of brine to the injector.

The timing of the salt-rinse step is such that the flow of water through the fluid distribution device and injector will continue for a considerable period of time after salt injection has ceased in order to rinse or flush out the brine from the softener bed I8. In other words, the brine flow continues for from three to about ten minutes and the rinse water flows for about flf; teen minutes thereafter.

After rinsing is completed, the master pilot valve disc 88 will have reached a position permitting resumption of the normal soitening opand valves 3, 4, 5 and 8 will be closed. The closing of valve 3 cuts off flow to the injector and the closing of valve 4 shuts off-flow through drain pipe I8. However, the opening of valve I allows water to flow into the softener tank and a back pressure is set up in the pipe line I3 which causes a portion of the water entering the distribution device to be diverted from the passage I53 into the oriflce 288 and chamber I88 of the distribution device C, and finally into pipe 25. The water brine is at the proper level in the brine tank, the b 'eration, that is, valves I and 21 will again be open astacao draining and refilling occurs each time that the softener bed is regenerated. It will also be apparent that the volume of the brine charge may be varied by adjusting the position of the collar 858 and 858' on the rod 858.

The distribution of fluid through the system to effect regeneration and the automatic operation of the brine tank having been described, consideration will now be given to the details of operation of the three pairs of valves I-2, 8-4, and 5-8, respectively, which affect the various steps of service," backwash," and salting -rinsing. For this purpose, it will be convenient to first refer to Figure 22, which diagrammatically illustrates the relative positions of the control knob 54, the ports and grooves of the master pilot valve 88 and the principal ports of the distribution plug X. In this view, as well as in Figures 23 and 24, the various grooves and ports have .been shown out of proportion in order to better illustrate registration and overlapping thereof.

It will be recalled. that the master pilot valve disc 88 is subjected to constant fluid pressure in the chamber 85'- of the master control device D. Hence, fluid under pressure is always present in the pressure groove 88 of the master. control valve 88 being admitted thereto by the throughports 82, 88, 84 and 85.

The exhaust groove 88 of the master pilot valve normally registers with the port I28 of the distribution plug X, and the leg 88 of the U-shaped passageway 81 is in alignment with the port I28. 7

The other leg 88 of said U-shaped passageway is continuously in registration with the axial port I25 01 the distribution plug X. Inasmuch as the passageway 81 controls the exhaust of fluid from the valves I to 8 and specifically from the pressure chambers of diaphragm valves I and 2, when ber I will be exhausted through passage I", and

groove I in the cover plate P; shallow groove I28, longitudinal passage I29, transverse pas-' flowing into the pipe 25, of course, will build up pressure in the diaphragm chamber in the valve 24, as described in my patent, supra, and when this pressure exceeds atmospheric, the valve will open and the water will readily pass through said valve, enter the pipe. 2i, and discharge therefrom into the lower portion of the brine tank B. I

Upon continued discharge, the level in the brine tank will gradually rise and thefloat 354 will be carried upwardly until it engages the collar 558 on the rod 858 and return the arm 32I and the with the valve 24 on the brine tank B that the brine is automatically withdrawn and fresh water is introduced into the brine tank to serve as sage I21 and port I28 in plug X; passage I88 in gasket I; port H8 in valve seat 85; U-shaped passageway 81 in the master pilot valve 88; .exhaust port 98 in valve seat passage I8'I in gasket I85; exhaust port I25 and passage I25 in plug X; passages I and I42 in cover plate P; opening I44 in gasket G; and finally through drain pipe I58. be opened by the pressure of the raw water in passage I88 of the body F upon exhaust of pressure fluid from valve chamber I.

Fluid under pressure is simultaneously exhausted from the chamber 2 of valve 2 by flowing through the passageway 2 and groove 2 in the cover plate P; shallow groove I 38', longitudinal passageway I38, transverse passageway I21 and port I28 in the plug X. The flow from port I28 is in the manner just described in connection with the exhausting of valve chamber I. Accordingly, the valve 2 will be opened by the pressure of the softened water in the passage I88 of the body F.

The pressure groove 88 of the master pilot valve 88 also normally registers with the ports III and I35 in the distribution plug X. The passages 85 and 83 are in direct alignment with the ports iii and I85, respectively, as shown in Figure 22, and therefore, pressure fluid may simultaneously flow through the passages 85 and 88, respectivea subsequent charge. This a 8180mm -75 1y, oi the pilot valve into said ports. The port Thus, the valve I can obviously bers of another pair of valves and 6. Application of pressure fluid to ports I3I and I35 maintains valves 3,4, ,5 and 6 closed while valves I and 2 areopen.

The flow to valve 3 is as follows: Pressure fluid passing through passage 85 and pressure groove 86 (see Figure 9) flows through the opening- III2 in the valve seat 95; opening III) in the'g'asket I85; port I3I, transverse passage I32, longitudinal passage I33 and shallow groove I33 in the plug X; and groove 3- and passage 3 in the cover plate P to the valve chamber 3. Pressure fluid is distributed from the transverse passage I32 to the valve 4 as follows: longitudinal passage I34 and shallow groove I34 in the plug X; groove 4 and passageway 4' in the cover plate P, and thence into the pressure chamber 4 of the valve 4.

The total pressure on' the diaphragm G .in chamber 3 exceeds that in passage I60 acting upon the underside of the valv guide II and valve 3 is thus maintained closed. Similarly,

valve 4 is maintained closed by applying to the diaphragm a total pressure exceeding that in passage I66.

of the valve 6, from the passage I36 to longitudinal passage I38 and shallow groove I38 in plug held in position by a screw il -which extends and 3-4, respectively. Hence, the valves I, 2,

3 and 4 will all be simultaneously maintained in closed position .by the admission of pressure fluid to their respective pressure chambers through the passageways already described.

The duration of the backwashing period is pre-.-

determined by the timing mechanism and the location of the ports in the master pilot valve disc and distribution plug X. Accordingly. the backa shorter backwash period. To this end an adjustable stop may be provided as shown in Figure I2. Here a slidable plate 51 is adjustably through an elongated slot 51 in said plate. A

projection 51 is carried by the plate and is adapted to be engaged by a control knob 54 to limit its movement clockwise. Any suitable gradua, tions may be provided upon the plate 51.

The relative positions of the ports and grooves of the master pilot valve 66 and the distribution plug X to efiect salting-rinsing is diagrammatically shown in Figure 24. Here, the exhaust groove 98 is in registration with the port I3I .of

the distribution plug. This port communicates with the pressure chambers 3 and 4 of valves 3 and 4 and when said port is open to exhaust,. these valves are permitted to open. It will be further noted that the pressure groove 86 is-in registration with the ports 'I28 and I35 of the distribution plug and that therefore pressure fluid is admitted into said ports. The port I28 com-j municates with chambers l and 2 of valves I X; groove 6 and passage 6 in the cover plate P and thence into said valve chamber 6.

From the foregoing it will be apparent that during normal softening service, a first pair of diaphragm valves I and 2 has the pressure thereon relieved so that the same can open; a second pair of diaphragm valves 3 and 4, and a third pair of diaphragm valves 5 and 6 are sublected to fluid pressure and are thereby maintained closed. The flow through the distribution device C in accordance with the above is schematically 'shown in Figure 19.

In order to initiate regeneration of the softening bed, the control knob 54 is turned clockwise approximately half a revolution. The turnin of the knob 54 rotates the master pilot valve 66 so thatthe grooves and ports thereof assume the position relative to the distribution plug X shown in Figure 23, whereby to'initiate the backwash.

ly indicated in Figure 20. It will be further notedfrom Figure 23 that the pressure groove 86 is in registration with the ports I28 and I3I controlling the flow of pressure fluid to valves l! and 2 and these valves will now be closed. The

port I35 communicates with chambers 5 and6 of valves 5 and *6 and these valves will also be closed. The flow through the distribution device when the valves 3 and 4 are open and the valves L 2, 5 and 6 are closed is diagrammatically illustrated in Figure 21.

The timing of the regeneration cycle may be as follows: backwashing may require five to ten minutes or less; brine flow may last for from three to ten minutes, and rinsing up to fifteen minutes or more; therefore, all told, the cycle of regeneration will require about thirty minutes.

Quiet operation of the various valves I, 2, 3, 4, 5 and 6 in the fluid distribution device is facilitated by locating the passageways I, 2, 3, 4, 5 andt respectively, at a point in the upper portion of the associated pressure chambers I, 2, etc., as shown in Figure 4. Such location prevents chattering, etc., by precluding the trapping of airinsaid chambers.

All of the parts of the foregoing apparatus which are subjected to contact with water or brine are preferably made of corrosion-resistant materials.

A further modification of the invention is illustrated in Figures 25, 26 and 2'7, wherein an arrangement is diagrammatically shown for manually controlling the regenerating-cycle of the Remote control of the softening apparatus, according to the present invention, is obtained by forming the master control apparatus D as a separate unit and installing it at any point desired. Such control is then connected by suitable tubing with the fluid distribution device C; the tubing being arranged so as to apply or exhaust pressure fluid to the diaphragm valves I, 2, 3, 4, and 5 to actuate these valves in the same sequence described hereinbefore.

Figure 26 diagrammatically illustrates in perspective the various tube connections from the control unit to the fluid distribution device. Figure 2'7 diagrammatically indicates with more particularity the manner of connecting certain of the passageways in the master control device with their cooperating passageways in the distribution device.

In efiecting remote control, one end of the master control housing 40 may be closed by a gasket 500 and a cover plate 50I secured by screws or other means to the housing 40. The gasket 500 and cover plate 50I are provided with passageways registering with the openings in the pilot valve seat 95 and with the pressure inlet opening I H6 in the housing 40.

503 and a plate 504 are secured to the boss I05.

The gasket is provided with an opening 2I5 and the plate 504 is provided with an aligned opening 2I6. One end of the tube 2I5 is received in the opening 2 Iii and its opposite end is received in the opening 2I 5. It will be understood, however, that fluid pressure need not necessarily be taken from the fluid distribution device C and that, if desired, thesame may be derived from V a source of supply more convenient to the control unit D. In such case the tube 2I5 will be connected with such source and not with the plate 504. The openings 2I8 and 2I6 are then unnecessary and are omitted.

The axial opening 09 in the master pilot valve disc 56, and which opening is aligned with the opening 99 in the valve seat, registers with an opening 99 in the gasket 500 and with an opening 99 in the cover plate 50I. A tube 99 is secured in the plate 50Iin registration with the opening 99. The opposite end of the tube 99 registers with an opening 99' in the gasket 503 and an opening 99 in the cover plate 504. The openings 99 and 99 in turn register with the axial exhaust opening I25 in the ,plug X. The opening I25 communicates with the passage I26, which merges into the passage MI in the boss I06, and the passageway I42. It will be recalled that the passageway I42 communicates with the drain pipe I50. Thus, it will be clear that fluid exhausted by the pilot valve disc 65 will be conducted through the tube 99 to the plug X in the fluid distribution device 0 and thence into the drain pipe I50. Here again, the tube connection with the plate 504 may be omitted, ii desired, and the fluid drained at a point adjacent to the control unit. 1

In a similar manner, the port I00 in the valve seat 95 is placed in communication with the port I28 in the plug X by a tube I00 extending from an opening I 00 in the cover plate 50I to an opening I00 in the cover plate 504; a tube IOI connects an opening I 0| in the cover plate. 50I (aligned with opening MI in valve seat with an opening IOI= in the cover plate 504 (aligned with port I35 in the distribution plug); and a tube i02 connects an opening I02 in-the cover plate 50I (aligned with opening I02 in valve seat 95) with an opening I02 in the cover plate 506 (aligned with opening I3I in the distribution plug).

The packing leakage port I55 of the housing 50 may be conveniently connected with the exhaust tube 99 by a short tube I45 as shown in Figures 26 and 27, or the same may be connected with any suitable drain.

It will be manifest from the foregoing that the master pilot valve 50 supplies fluid to the ports in the plug X through the various tubes 99, 00, IOI and I02 in a manner similar to that when the parts are arranged as shown in Figure 3; but the use of the tubes provides the additional convenience of enablingthe disposition of the master control valve at a point remote from the softening apparatus itself, as diagrammatically illustrated in Figure 27.

The term fluid distribution unit, wherever such term is specifically employed in any of the claims herein, is intended in such claims to embrace a structure wherein a plurality of valves is contained in a body or housing, ascontradistinguished from an arrangement such as disclosed, for example, in Pick Patent No. 2,076,321, wherein the several separate .valves are scattered and interconnected by an elaborate pipe system.

While the invention has been described and illustrated in several forms, the same may be embodied in other arrangements without departing materially from the spirit thereof or the scope of the appended claims.

I claim:

1. A fluid distribution device comprising, a body; a cover plate, a plurality of diaphragm valves in said body; a pressure chamber in said cover plate above each valve, said cover plate having passageways including substantially radial grooves cut in the inner face thereof for admitting pressure fluid to said pressure chambers for operating said diaphragm valves.

2. A fluid distribution device comprising, a body; a cover plate; a plurality of pressure responsive diaphragm valves in said body; a fluid distribution plug in said cover plate, said plug and cover plate having cooperating passageways including communicating grooves in the face of said plug and cover plate adjacent the diaphragm of said valves for admitting pressure fluid to and exhausting pressure fluid from said diaphragm valves.

3. A fluid distribution device for use with a fluid treating apparatus comprising: a housing including a bottom wall and side walls extending upwardly therefrom; partition means between said side walls defining a series of passageways; a series of valve seats on said partition means between said side walls for allowing flow of fluid between certain of said passageways; said housing having an inlet opening for untreated fluid and an outlet opening for discharging said untreated fluid into a fluid treating apparatus; an inlet opening for admitting treated fluid into said housing from said fluid treating apparatus and a phragm;

housing, each valve being cooperabie with one closed, untreated fluid will flow through said housing to the treating apparatus and treated fluid will be returned from and flow through said housing and out of the discharge opening for treated fluid.

4. A fluid distribution device for use with a water softener comprising: a housing including a bottom wall and spaced side walls extending upwardly therefrom; partition means between said side walls defining a series of passageways; a series of valve seats on said partition means between said side walls for allowing flow of fluid between certain of said passageways; said housing having an inlet opening for raw water and an outlet opening for discharging said raw water into a water softener; an inlet opening for admitting softened water into said housing and a discharge opening for discharging softened Water from said housing; a series of valves in said housing, each valve being cooperable with one of said valve seats, said valves being arranged so that when only two of said valves are open and the remaining valves are closed, raw water will flow through said housing to the softener and softened water will be returned from said softener and flow through said housing and out of the discharge opening for softened water. I

5. A fluid distribution device compr sing, a body; a cover plate for said body; a diaphragm interposed between said body and cover plate; a valve seat in said body; a valve secured to said diaphragm and arranged to engage said valve seat; a cavity formed in said cover plate and providing a pressure chamber above said diafiuid to saidpressu'rechamber including a substantially radially extending groove formed in the face of said' cover plate adjacent said diaphragm and a passage extending from one end of said groove and opening into the deepest part of said cavity.

6. Fluid distribution apparatus and control means therefor comprising, a housing; a pressure chamber in said housing; a rotatable pilot valve in said pressure chamber;a shaft connected with sa d pilot valve for rotating the same; means for supplying fluid under pressure to said pressure chamber, said pilot valve being arranged in said pressure chamber so that said fluid urges it against its seat; packing means surrounding said shaft for preventing the escape of pressure fluid from sa d chamber along said shaft; a fluid distribution device having a plurality of pressure responsive valves therein and a pressure chamber above each of said valves; ports in said pilot valve and passageways in said fluid distribution device for admitting and exhausting operating fluid from said pressure chambers; and common drain means for draining spent operating fluid and any leakage which 'may get past said shaft packing means from said fluid distribution device and housing.

7. A fluid distribution device comprising: a body including generally concentric side walls and partitions between said side walls defining aseries of passageways, said partitions including vertical portions connected by horizontal portionsi a plurality ofvalve seats on said horizontal portions for allowing flow of fluid from one passageway to another; valve means adapted to engage said valve seats; a cover plate enclosing and means for admitting operating flow through said valve seats,

said valve means; and means for controlling the, operation of said valve means to cut off or allow 8. A fluid distribution device comprising: a hollow housing having an opening for admitting a fluid thereinto; a second opening for the discharge of said fluid therefrom; a continuous passageway in said housing between said inlet and discharge openings; and three valves operatively associated with sa d passageway, one of said valves being located adjacent said inlet opening,

another of said valves being located adjacent said discharge opening and still another of said valves being located-intermediate the other two valves,

said valves being arranged to be operated so that flow occurs between said inlet and discharge openings directly through said pasageway when the valve adjacent said discharge opening only is open and the other two valves are closed.

9. A fluid distribution device comprising: a hollow housing havingan opening for admitting fluid thereinto; a second opening for the discharge of said fluid therefrom; a continuous passageway in said housing between said inlet and discharge openings; and three valves operatively associated with said passageway, one of said valves being located adjacent said inlet opening, another of said valves being located adjacentsaid discharge opening, and still another of said valves being located intermediate the other two valves; an inieetor in said housing arranged to discharge into said discharge opening, said injector. being adapted to be connected with a supply of material to bepassed through said discharge opening; and passage means n said, housing leading to said injector. said intermediate valve being positioned to control flow between said passageway and said passage means, said valves being arranged to be operated so that flow occurs to said injector when the intermediate valve only is open and the other two valves are closed.

10. A fluid distribution device comprising: a housing having an inlet opening, an outlet opening, a return opening, a service opening, and a waste opening; a cover plate; a diaphragm between said cover plate and housing; means se-,

ings, and sa d return and waste openings when the pair of valves associated therewith is open; and the third pair of passageways establish communication between said inlet and outlet openlugs, and said return and service openings when the pair of valves associated therewith is open;

"pressure chamber means on one side of said diaphragm associated with each pair of valves; and control means for said pairs of valves arranged and constructed to exhaust operating fluid from the pressure chamber means associated with each of said pairs of valves in succession to effect opening thereof, and to simultaneously admit operating fluid tothe pressure chamber means associated withthe 'otherpairs of valves to maintain the same closed.

11. A fluid distribution device comprising: a. generally circular housing having an inlet opening, an outlet opening, a return opening, a service:

pairs of passageways therein with each pair-ineluding a pair of cooperating valves each consisting of a valve seat in said housing and a valve member connected with said diaphragm; the valves associated with the respective pairs of passageways being diametrically disposed on equal radii; said passageways and valves being arranged and constructed so that the first pair of passageways establish communication between said inlet and return openings, and said return and waste openings when the pair of valves associated therewith are open; the second pair of passageways establish communication between said inlet and outlet openings, and said return and waste openings when the pair of valves associated therewith are open? and the third pair of passageways establish communication between said inlet and outlet openings, and said return and service openings when the pair of valves associated therewith are open; pressure chamber means in said cover for each pair of valves; and control mean for said pairs of valv'es arranged and constructed to exhaust operating fluid from the pressure chamber means associated with each of said pairs of valves in succession to effect opening thereof, and to simultaneously admit operating fluid to the pressure chamber means associated with the other pairs of valvesto maintain the same closed.

12. A fluid distribution device comprising: a housing having an inlet opening, an outlet opening, a return opening, a service opening, and a waste opening; a cover plate; a diaphragm between said cover plate and housing; means securing said cover plate, diaphragm, and housing in assembled relation, said housin having three pairs of passageways therein with each pair including a pair of cooperating valves each consisting of a valve seat in said housing and a valve member carried by said diaphragm, said passageways and valves being arranged and constructed so that the first pair of passageways establish communication between said inlet and return openings, and said return and waste openings when the pair of valves associated therewith is open; the second pair of passageways establish communication between said inlet and outlet openings, and said return and waste openings when the pair ofvalves associated therewith is open; and the third pair of passageways establish communication between said inlet and outlet openings, and said return and service openings when the pair of valves associated therewith is open; pressure chamber means on one side of said diaphragm associated with each pair at valves; a fluid distribution plug mounted centrally in said cover plate, said fluid distribution to fourth passage means having a valve seat plug and cover having three passageways respectively interconnecting the pressure chamber means associated with each pair of valves, said :fluid distribution plug having a separate port leading to each of said last-mentioned passagein'assembled relation, said housing having three ways; and pilot valve means includingla ported pilot element for successively exhausting spent operating fluid from the pressure chamber means associated with one pair of valves through one of said ports and simultaneously admitting op-- housing having an inlet opening, an outlet opening, a return opening, a service opening, and a waste opening; a first passage means in said housing having a valve seat arranged to establish communication between said inlet and outlet openings; a second passage means in said housing having a valve seat arranged to establish communication between said return and service openings: a third passage means in said housing having a valve seat arranged to establish communication between said inlet opening andsaid return opening; a fourth passage means in said housing having a valve seat arranged to establish communication between said outlet and waste openings; a fifth passage means in said body having a valve seat arranged to establish communication between said inlet and outlet openings; a sixth passage means in said body having a valve seat arranged to establish communication between said return opening and said waste opening; closure means in said housing cooperatively arranged to engage each of said seats to control flow therethrough, the closure means and cooperating seats associated with said first and second passage means constituting a first pair of valves, the closure means and cooperating seats associated with said third and fourth passage means constituting a second pair 01: valves. and the closure means and cooperating seats associated with said fifth and sixth passage means constituting a third pair of, valves; and control means for said valves arranged and constructed to efiect opening of one pair of valves and to simultaneously eflect closing of the other two pairs of valves, and to effect opening of each-pair housing having an inlet opening, an outlet opening, a return opening, a service opening, and a waste opening; a first passage means in said housing having a valve seat arranged to establish communication between said inlet and outlet openings; a second passage means in said housing having a valve seat arranged to establish communication between said return and service openings; a third passage means in said housing, consisting of portions of said first and second passage means, haviug a valve seat arranged toestablish communication between said inlet opening and said return openings; a fourth passage means in said housing, including a portion of said first passage means, having a valve seat arranged to establish communication between said outlet and waste openings; a fifth passage means in said housing, including portions 'of said first passage means and a valve seat arranged to establish communication between said inlet and outlet openings; a sixth passage means in said housing, consisting of portions of said second and said ranged to establish communication between said return opening and said waste opening; closure means in said housing cooperatively arranged to engage each of said seats to control flow therethrough, the closure means and cooperating seats associated with said firstand second passage means constituting a first pair of valves, the closure means and cooperating seatsassociated with said third and fourth passage means con- 

